MANUFACTURING - WATER VALVES - INDUSTRIAL VALVES - PENSTOCKS AND GATES - RADIAL GATES - SPECIAL APPLICATIONS NEEDLE VALVES DI NICOLA INFINAM s.r.l. Legal seat: Via Mazzini, 11 6600 S. Giovanni Teatino (CH) - ITALY Tel. +9 085 9049480 - Fax +9 085 9049481 Web site: www.dinicolavalves.com email: sales@dinicolavalves.com 1
GENERAL CHARACTERISTICS The network has gained increasing importance trying to conciliate available water reserves and the always increasing request for water. Usually, the network capacity is always greater than the effective request; this implies the necessity to utilize devices able to control the distribution of the water without wasting it. Needle valve is especially designed to realize the function of regulating the water flow, maintaining an easy handling even in circumstances which comport heavy hydrostatic loads at its mouth and a very different excercise pressure. The use of needle valve with the aid of actuators allows to utilize it in control systems with very different functions. Water flow regulation actuated by needle valve is done by the horizontal sliding of an obturator, mechanically acted by an handle with a connecting rod-movement. Thanks to a special balanced chamber every kind of vibration or anomalous oleodynamic load are eliminated, moreover its internal shape is especially made to avoid the incurring of cavitation. The obturator moves in position to close the valve following the direction of the flow and allowing to control the change of the water flow without efforts. CAVITATION CAUSES AND EFFECTS Either we regulate or stop a water flow in the concentration area, a reduction of the pressure occurs. When the pressure drops below the vapour saturation in the water, gases are generated with subsequent release of vapourbubbles in the zone of depression. In this environment the bubbles, pushed by the flow, caused by the pressure difference downstream, implode reverting back to liquid form and damaging the inner walls of the piping. The shocks due to the high pressure localized on the walls of the valves and the pipes cause great damages. to them added to the heavy noise and destructive vibrations. The special profile of the DI NICOLA valve, drives the water flow against the walls of the body of the valve and of the nearby conduit creating, in its interior, a collapse area for the vapour bubbles that prevents them to reach the walls of the valve or of the conduit creating, in its interior, a collapse area for the vapour bubbles that prevents them to reach the walls of the valve or of the conduit and to damage them.
MATERIALS AND DIMENSIONS 1 4 5 6 8 9 1) Body: spheroidal cast iron GGG50 - Fe S5JR ) Stem: stainless steel AISI 40 - AISI 16 ) Crank: spheroidal cast iron GGG50 - Fe S5JR 4) Connecting rod: stainless steel AISI 04 - Fe S5JR 5) Shutter: stainless steel AISI 04 - AISI 16 6) O-ring: neoprene ) Support: stainless steel AISI 04 - Fe S5JR 8) Sealing rubber: neoprene 9) Collar: stainless steel AISI 04 - Fe S5JR DN C D L B A DIMENSIONS IN MM DN A B C D (PN ) D (PN16) D (PN 5) D (PN 40) L 0 150 1 1 0 0 5 5 00 15 180 15 15 50 50 0 0 50 150 14 14 85 85 00 00 00 00 40 40 40 60 5 400 50 90 0 0 95 405 45 450 500 00 0 6 55 445 460 485 515 600 50 80 80 85 505 50 555 580 00 400 40 4 0 565 580 60 660 800 450 40 0 40 615 640 60 685 900 500 455 88 60 15 660 55 00 600 546 44 465 80 840 845 890 0 00 6 51 55 895 9 960 995 1400 800 15 58 59 15 5 85 1140 1600 900 80 685 655 1115 115 1185 150 1800 00 80 0 50 155 1 160 000 Larger diameters are also available on request on electrowelded steel.
DOCUMENTATION Report made on the bases of the Di Nicola valve testing, realized by Istituto di Idraulica Agraria - Università di Napoli (1991). Thecnical report on hydraulic behaviour Aim: The following report is to illustrate the technical reasons by which the valve is not subject to cavitation phenomena when used in a correct way. Pressure course within the valve (fig. 1) Piezometric pressure in the hydraulic network follows the direction indicated on fig. n 1 A B C D Η δη Section A= Upstream pressure (Hm) Section C= Minimum pressure within the valve Section D= Downstream pressure (Hv) The difference (Hm-Hv) = Η represents the effective head loss. The value of the head loss is defined at each step by the following formula Η = Κ n V g Hm Hv Kn = Head loss coefficient at the opening degree Valvola regolatrice di The apparent head loss (δη) is instead recovered by downstream conduit after few diameters (D section), so it is not taken in account in the head losses, anyway it is very important to define the value of the pressure within the valve. Calculation of the minimum pressure value in section C - (fig. ) Fig. 1 During the tests on the sample have been studied the minimum values of the pressure on the section C. Medium values of Η and δη at different opening degrees have been scheduled to obtain diagram (fig. ) To evaluate the minimum value of the pressure on section C, is necessary to observe the piezometric curve at the different opening degrees. The C pressure is valid at every opening degree. P c = Hv - δη δη / Η 0,0 0,5 0,0 Water head chart inside the valve If the C pressure is > than atmospheric pressure, cavitation does not occur. If the C pressure is < than atmospheric pressure, it is necessary to analyze the situation to provide the system with devices able to prevent cavitation. CONCLUSIONS: Analyzing the diagram (FIG.) it is easy to see the good behaviour of the valve in relation of cavitation. Thus, the anti-cavitation ring is not needed in standard configurations. 0,15 0, 0,05 0 0 40 50 60 0 80 90 0 Η open degree chart Fig. open degree of the obturator
NEEDLE VALVE DIMENSIONING The needle valve dimensioning is not based on the conduit diameter but on the pressure conditions in exercise and on the maximum and minimum values of the water flow. Required data Dimensioning example Maximum flow required (Q - m /s.) Q = 0,80 m /sec. Maximum upstream pressure (Hm stat - meters of water column) Hm stat = 0m.w.c. Upstream pressure at maximum flow (Hm min - m.w.c.) Hm min = 16m.w.c. Maximum downstream pressure (Hv max - m.w.c.) Hv max = 1m.w.c. 1. Determination Η available on the valve to deliver the flow Q: Η = Hm min - Hv max Η = 16-1 = 4 m.w.c.. Determination of the nominal pressure class (NP) PN = 1,5 x Hm stat PN = 0 x 1,5 = 45 m.c.a. 4,5 Bar The nominal pressure chosen for the valve will be those immediately above the calculated value. The choice among the standardized ISO classes, in our case, will be NP 6.. Determination of the nominal diameter. The value of the diameter will be obtained by the following formula: D = 0,194 Q 1/ Η 0,194 0,8 1/4 0,455 m. The chosen diameter among the standardized ISO diameters will be: ND 500 This formula is not available when a slotted cylinder is required. OUTLET FLOW: The outlet flow can put on three sections: 98 6 5 4 000 C. head loss diagram 1 Standard section. For normal control flow (see curve 1. head loss coefficient diagram). 98 6 5 4 00 Discharge section. For control flow in presence of high pressure into the pipe line. (see curve. head loss coefficient diagram). 98 6 5 4 0 1 Discharge section with very high pressure into the pipe line. In this case the inner cylinder shall have longitudinal slot. (see curve. head loss coefficient diagram). 98 6 5 4.0 4.0. 1 opening degree % 0 90 80 0 60 50 40 0 0 0
USE OF THE VALVE This type of valve can be supplied as a solution to several flow control problems. The followings are the most frequently encountered: (a.) Down pressure control Needle valve, with down stream positioned pressure gauge controlled by computer, is a very good solution to keep the pressure constant into the down stream pipe line even in presence of big changes of pressure range into the upper stream adductor pipe line. Principle sketch-plan n 1 1.)Needle valve 4.)Local control electric diagram.)pressure gauge 5.)Remote control and signaling panel.)computer 6.)Relief valve (b.) Flow control valve On very big hydraulic plants, these valves are also used for flow control systems. In this case the Needle valve provided of flow meter is an excellent instrument for flow control crossing a fixed point of a complicate hydraulic circuit. it is also possible to program a water delivery according to a prefixed law that can be changed during the time, as required in modern irrigation plants. Principle sketch-plan n 1.)Needle valve 4.)Flow meter.)valve control 5.)Flow indicator.)computer 6.)Remote control (c.) Upper stream pressure control Needle valve with an upper stream pressure gauge controlled by a computer is an effective system to control the piezometric energy of the upper pipe line. This system is normally used on big hydraulic circuit as for acqueduct and irrigation plants. Principle sketch-plan n 1.)Needle valve 4.)Pressure gauge.)valve control 5.)Remote control.)computer
NOTES ON INSTALLATION - Di Nicola needle valve can be installed vertically, remembering to follow the direction of the arrow shown on them - It is possible to install Di Nicola needle valves of dimensions smaller than conduit diameter as their design is studied in base at the flow speed. It is recommended to use a Venturi pipe upstream and downstream of the valve. - In case a dismantling joint is used in conjuction with the valve, it is suggested to install it upstream of the valve. DI NICOLA needle valves can be supplied with a wide range of accessories: * ANTICAVITATION RING * SLOTTED CYLINDER * EXTENSION PILLAR * EXTENSION SPINDLES * GSM OPENING DEGREE CONTROL * SOLAR PANNEL POWER CONTROL * MECHANICAL AND GRAVITY POWERING CONTROL * OLEODYNAMIC ACTUATION * PNEUMATIC ACTUATION DI NICOLA needle valves can be used in several applications: * Shut-off valves in condition of high exercise pressure and high flow speed * Anti water-hammer control valve * Pressure regulating valve * Pressure relief valve * Security valve * Bottom outlet for dams * Tank level control system Why to choose a DI NICOLA Needle Valve 1) The dimensioning is based on the exercise conditions; ) The use of anti cavitation devices is rarely required; ) Self-lubrificating bushing are used to sustain the stem; 4) Sealing by O-ring realized only in position closed ; 5) DI NICOLA needle valve is certified by a third party; 6) Di Nicola builds and installs valves since 1981; ) The costs are lower when using a valve with dimensions inferior to the conduit diameter; 8) Reduced head losses; 9) Increased security even in condition of heavy load; ) High durability of the O-ring and easy upkeep of the valve; 11) Certified guarantee of performance; 1) Trustfulness supported by a very long list of references;
CONSORZIO DI BONIFICA DELLA CAPITANATA FOGGIA SPINDLE VALVE ND 0 ELECTRICALLY OPERATED DIGA DI ARMINOU (CYPRUS) NEEDLE VALVE CONSORZIO ND 1400 ELECTRICALLY OPERATED DI BONIFICA DI NARDO LECCE / NEEDLE VALVE ND 0 WITH HYDRAULIC ACTUATOR